Abstract
B cells have long been regarded as cells specialized in antibody production. However, recent studies have shown that the roles of B cells are diverse. One of their key functions is that B cells are involved in the regulation of the immune system by producing cytokines. In fact, B cell depletion therapy is effective in a variety of autoimmune diseases, indicating that B cells also play a central role in autoimmune diseases. The B cells are composed of various subsets. Because the function of each B cell subset differs from one another, it is important to understand the role of each in the autoimmune disease pathogenesis. Recently, B cells have been shown to be classified by their producing cytokines. This article outlined B cell subsets based on the cytokines they produce.
Keywords: B Cell Subset; Effector B Cell; Regulatory B Cell; Cytokine-Producing B Cell; Autoimmune Disease
Introduction
Recent advances in immunology have revealed that B cells have a variety of functions [1]. Although originally thought to be solely responsible for producing antibodies, it has now been suggested that B cells play a pivotal role in the immune system via antigen presentation and cytokine production (Figure 1). B cells are also important in autoimmune diseases, and in particular, B cell receptor-mediated auto antigen stimulation may induce activation of auto antigen-reactive B cells and cytokine production from them, which may play a major role in the disease development. However, due to technical difficulties, direct examination of autoantigenreactive B cells has not yet been carried out, leaving their function unclear [2]. Nevertheless, the importance of B cells in autoimmune diseases is evident from the fact that B cell depletion therapy is useful for many systemic autoimmune diseases such as vasculitis, rheumatoid arthritis, systemic lupus erythematosus, and systemic sclerosis [3]. Since the therapeutic effect of B cell depletion is not necessarily exerted by lowering the titer of auto antibodies, it is strongly suggested that B cells themselves affect autoimmune diseases in an antibody-producing ability-independent manner. More specifically, it is hypothesized that B cells can influence the function of other immune cells, including T cells, by producing cytokines [4]. This article summarized three major B cell subsets that are identified by cytokine production.
B Cell Subsets
Recent studies have indicated that there are two types of B cell classification: the subsets divided by differentiation stage and the functional subsets divided by the cytokines they produce [5]. Functional B cell subsets have been shown to exist as subsets of effector B (Be) cells that activate immunity and regulatory B (Breg) cells that suppress immunity (Figure 2). Furthermore, Be cells can be divided into Be-1 cells that produce T helper (Th)1-type cytokines and Be-2 cells that produce Th2-type cytokines.
Be cells
Be-1 cells produce Th1-type cytokines such as interferon (IFN)-γ and interleukin (IL)-12 upon stimulation by Th1 cells or Th1-type response-inducing antigens [6]. Be-1 cells were identified in an infection experiment that induced a Th1-type response in mice. On the other hand, Be-2 cells were identified in a model of parasitic infection [6]. Be-2 cells have been shown to produce IL-2, IL-4, IL-12, and other Th2-type cytokines in response to Th2 cell stimulation, Th2-type antigen stimulation, and allergic reactions. B cells are classified into B1 and B2 cells, depending on their developmental origin and distribution. B1 cells originate in the liver during embryonic period and are distributed in mucosal tissues, abdominal cavity, and thoracic cavity. B2 cells come from the bone marrow. Furthermore, based on their distribution in lymphoid tissues, B2 cells are divided into marginal zone B cells and follicular B cells. Marginal zone B cells are important for innate immunity, while follicular B cells are crucial for antigenspecific acquired immunity. Recent studies have shown that Be cells are present in follicular B cells [7]. Thus, it has been suggested that Be cells may be intimately involved in autoimmune diseases through autoantigen-specific responses. However, to the best of our knowledge, no studies have directly examined autoantigen-reactive Be cells in patients with autoimmune diseases. This is because the amount of cytokines produced by B cells is small compared to dendritic cells, macrophages, and T cells, and in addition, there are only a few disease specific autoantigen-reactive B cells in the patient’s body, making direct studies difficult. Therefore, there is not much knowledge available on the relationship between Be cells and autoimmune diseases.
Breg Cells
Breg cells are thought to exert an immunosuppressive function by producing inhibitory cytokines such as IL-10, IL-35, and transforming growth factor-β [8,9]. Unlike Be cells, which are relatively confined to follicular B cells, Breg cells are present in various B cell subpopulations, including B1a cells showing CD5 positivity in B1 cells, transitional B cells, follicular B cells, and marginal zone B cells. The function of Breg cells has so far been mainly defined by their ability to produce anti-inflammatory cytokines, but several studies in mice have suggested that the role of Breg cells depends on which fraction they belong to [10,11]. These studies have shown that Breg cells in the B1a fraction suppress the excessive immune response to innate immunity during the neonatal phase, and that Breg cells in marginal zone B cell or transitional B cell fractions, which are B2 cells, suppress the autoimmune response during the adult phase. In humans, Breg cells with traits of marginal zone B cells that strongly express CD1d or transitional B cells that express both CD24 and CD38 are considered to be responsible for the suppression of activity in several autoimmune diseases [12]. In addition, since adoptive transfer of Breg cells markedly suppresses the symptoms of many autoimmune disease models, its use as a treatment for humans is notable [13].
Conclusion
In addition to antibody production and antigen presentation, B cells have been shown to play a variety of roles through cytokine production. However, the autoantigen-specific response, which is the main feature of B cells in autoimmune diseases, has not been fully studied in autoimmune disease patients. The reasons for this are the low number of disease specific autoantigen-reactive B cells in patients and the low amount of cytokines produced by B cells, as mentioned above. To solve this conundrum, we have developed a unique system using microfluidics to measure very small amounts of cytokines at the ag-fg/ml levels through collaborative research in medical and engineering [14-17]. Studies using this system have shown that IL-10-producing B cell population exist even among autoantigen-reactive B cells, suggesting that not all autoantigenreactive B cells are pathogenic [14]. In fact, B cell depletion therapy has been shown to be effective in several autoimmune diseases, but there is still room for improvement in the general removal of all B cells, as adverse events such as infections have sometimes been observed. However, the detailed functional analysis of B cells ultimately needs to be performed in a single cell, because not only the diverse subsets of B cells exist, but also the differences between individual B cells according to the different B cell receptors [18]. It is expected that further innovative B cell studies, such as single B cell analysis at protein levels, will clarify the relationship between B cell subsets in the context of cytokine production and autoantigenreactive B cells, which will lead to the discovery of novel therapeutic targets.
Conflict of Interest
The authors have declared that no conflict of interest exists.
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